Dependence of RGS9-1 membrane attachment on its C-terminal tail.

RGS9-1 is a GTPase-accelerating protein (GAP) required for rapid recovery of the light response in vertebrate rod and cone photoreceptors. Similar to its phototransduction partners transducin (G(t)) and cGMP phosphodiesterase, it is a peripheral protein of the disc membranes, but it binds membranes much more tightly. It lacks the lipid modifications found on G(t) and cGMP phosphodiesterase, and the mechanism for membrane attachment is unknown. We have used limited proteolysis to generate a fragment of RGS9-1 that is readily removed from membranes under moderate salt conditions. Immunoblots reveal that this soluble fragment lacks a 3-kDa fragment from the C-terminal domain, the only domain within RGS9-1 that differs in sequence from the brain-specific isoform RGS9-2. Recombinant fragments of RGS9-1 with or without the partner subunit G beta(5L) were constructed with or without the C-terminal domain. Those lacking the C-terminal domain bound to photoreceptor membranes much less tightly than those containing it. Removal by urea of G beta(5L) from endogenous or recombinant RGS9-1 bound to rod outer segment membranes left RGS9-1 tightly membrane-bound, and recombinant RGS9-1 was urea-soluble in the absence of membranes. Thus the C-terminal domain of RGS9-1 is critical for membrane binding, whereas G beta(5L) does not play an important role in membrane attachment.

REST acts through multiple deacetylase complexes.

The RE1 binding silencer protein REST represses neuronal-specific gene expression in nonneuronal cell types. In this issue of Neuron, Ballas et al. show that REST inhibits gene expression via the recruitment of multiple histone deacetylase complexes.

Phosphorylation of RGS9-1 by an endogenous protein kinase in rod outer segments.

Inactivation of the visual G protein transducin, during recovery from photoexcitation, is regulated by RGS9-1, a GTPase-accelerating protein of the ubiquitous RGS protein family. Incubation of dark-adapted bovine rod outer segments with [gamma-(32)P]ATP led to RGS9-1 phosphorylation by an endogenous kinase in rod outer segment membranes, with an average stoichiometry of 0.2-0.45 mol of phosphates/mol of RGS9-1. Mass spectrometry revealed a single major site of phosphorylation, Ser(475). The kinase responsible catalyzed robust phosphorylation of recombinant RGS9-1 and not of an S475A mutant. A synthetic peptide corresponding to the region surrounding Ser(475) was also phosphorylated, and a similar peptide with the S475A substitution inhibited RGS9-1 phosphorylation. The RGS9-1 kinase is a peripheral membrane protein that co-purifies with rhodopsin in sucrose gradients and can be extracted in buffers of high ionic strength. It is not inhibited or activated significantly by a panel of inhibitors or activators of protein kinase A, protein kinase G, rhodopsin kinase, CaM kinase II, casein kinase II, or cyclin-dependent kinase 5, at concentrations 50 or more times higher than their reported IC(50) or K(i) values. It was inhibited by the protein kinase C inhibitor bisindolylmaleimide I and by lowering Ca(2+) to nanomolar levels with EGTA; however, it was not stimulated by the addition of phorbol ester, under conditions that significantly enhanced rhodopsin phosphorylation. A monoclonal antibody specific for the Ser(475)-phosphorylated form of RGS9-1 recognized RGS9-1 in immunoblots of dark-adapted mouse retina. Retinas from light-adapted mice had much lower levels of RGS9-1 phosphorylation. Thus, RGS9-1 is phosphorylated on Ser(475) in vivo, and the phosphorylation level is regulated by light and by [Ca(2+)], suggesting the importance of the modification in light adaptation.

Structural determinants for regulation of phosphodiesterase by a G protein at 2.0 A.

A multitude of heptahelical receptors use heterotrimeric G proteins to transduce signals to specific effector target molecules. The G protein transducin, Gt, couples photon-activated rhodopsin with the effector cyclic GMP phosophodiesterase (PDE) in the vertebrate phototransduction cascade. The interactions of the Gt alpha-subunit (alpha(t)) with the inhibitory PDE gamma-subunit (PDEgamma) are central to effector activation, and also enhance visual recovery in cooperation with the GTPase-activating protein regulator of G-protein signalling (RGS)-9 (refs 1-3). Here we describe the crystal structure at 2.0 A of rod transducin alpha x GDP x AlF4- in complex with the effector molecule PDEgamma and the GTPase-activating protein RGS9. In addition, we present the independently solved crystal structures of the RGS9 RGS domain both alone and in complex with alpha(t/i1) x GDP x AlF4-. These structures reveal insights into effector activation, synergistic GTPase acceleration, RGS9 specificity and RGS activity. Effector binding to a nucleotide-dependent site on alpha(t) sequesters PDEgamma residues implicated in PDE inhibition, and potentiates recruitment of RGS9 for hydrolytic transition state stabilization and concomitant signal termination.

RGS proteins: lessons from the RGS9 subfamily.

RGS proteins enhance the time resolution of G protein signaling cascades by accelerating GTP hydrolysis of G alpha subunits of heterotrimeric G proteins. RGS9-1, a photoreceptor-specific RGS protein, is the first vertebrate member of this sizeable family whose physiological function in a well-defined G protein pathway has been identified. It is essential for normal subsecond recovery kinetics of the light responses in retinal photoreceptors. Understanding this role allows RGS9-1 to serve as a useful model for understanding how specificity and regulation of RGS function are achieved. In addition to the catalytic RGS domain, shared among all members of this family, RGS9-1 contains several other domains, which are also found in a closely related subset of RGS proteins, the RGS9 subfamily. One of these domains, the G gamma-like (GGL) domain, has been identified as the attachment site for G beta 5 proteins, which act as obligate subunits for this subfamily. Results from RGS9-1 and other subfamily members suggest that specificity is achieved by cell type-specific transcription, RNA processing, and G beta 5-dependent protein stabilization. In addition, membrane localization via specific targeting domains likely plays an important role.

Multiple zinc binding sites in retinal rod cGMP phosphodiesterase, PDE6alpha beta.

The photoreceptor cGMP phosphodiesterase (PDE6) plays a key role in vertebrate vision, but its enzymatic mechanism and the roles of metal ion co-factors have yet to be determined. We have determined the amount of endogenous Zn(2+) in rod PDE6 and established a requirement for tightly bound Zn(2+) in catalysis. Purified PDE6 contained 3-4-g atoms of zinc/mole, consistent with an initial content of two tightly bound Zn(2+)/catalytic subunit. PDE with only tightly bound Zn(2+) and no free metal ions was inactive, but activity was fully restored by Mg(2+), Mn(2+), Co(2+), or Zn(2+). Mn(2+), Co(2+), and Zn(2+) also induced aggregation and inactivation at higher concentrations and longer times. Removal of 93% of the tightly bound Zn(2+) by treatment with dipicolinic acid and EDTA at pH 6.0 resulted in almost complete loss of activity in the presence of Mg(2+). This activity loss was blocked almost completely by Zn(2+), less potently by Co(2+) and almost not at all by Mg(2+), Mn(2+), or Cu(2+). The lost activity was restored by the addition of Zn(2+), but Co(2+) restored only 13% as much activity, and other metals even less. Thus tightly bound Zn(2+) is required for catalysis but could also play a role in stabilizing the structure of PDE6, whereas distinct sites where Zn(2+) is rapidly exchanged are likely occupied by Mg(2+) under physiological conditions.

Cloning and characterization of RGS9-2: a striatal-enriched alternatively spliced product of the RGS9 gene.

Regulators of G-protein signaling (RGS) proteins act as GTPase-activating proteins (GAPs) for alpha subunits of heterotrimeric G-proteins. Previous in situ hybridization analysis of mRNAs encoding RGS3-RGS11 revealed region-specific expression patterns in rat brain. RGS9 showed a particularly striking pattern of almost exclusive enrichment in striatum. In a parallel study, RGS9 cDNA, here referred to as RGS9-1, was cloned from retinal cDNA libraries, and the encoded protein was identified as a GAP for transducin (Galphat) in rod outer segments. In the present study we identify a novel splice variant of RGS9, RGS9-2, cloned from a mouse forebrain cDNA library, which encodes a striatal-specific isoform of the protein. RGS9-2 is 191 amino acids longer than the retinal isoform, has a unique 3' untranslated region, and is highly enriched in striatum, with much lower levels seen in other brain regions and no expression detectable in retina. Immunohistochemistry showed that RGS9-2 protein is restricted to striatal neuropil and absent in striatal terminal fields. The functional activity of RGS9-2 is supported by the finding that it, but not RGS9-1, dampens the Gi/o-coupled mu-opioid receptor response in vitro. Characterization of a bacterial artificial chromosome genomic clone of approximately 200 kb indicates that these isoforms represent alternatively spliced mRNAs from a single gene and that the RGS domain, conserved among all known RGS members, is encoded over three distinct exons. The distinct C-terminal domains of RGS9-2 and RGS9-1 presumably contribute to unique regulatory properties in the neural and retinal cells in which these proteins are selectively expressed.

High expression levels in cones of RGS9, the predominant GTPase accelerating protein of rods.

RGS9 is a member of the RGS family of GTPase accelerating proteins (GAPs) for heterotrimeric G proteins. We have explored its contribution to GTPase acceleration in mammalian rod and cone photoreceptors. When RGS9 was specifically removed from detergent extracts of rod outer segments by immunodepletion, the extracts lost nearly all of their GAP activity stimulatable by the inhibitory subunit of cGMP phosphodiesterase. Immunolocalization using monoclonal antibodies and confocal microscopy revealed that RGS9 is present in cones at significantly higher levels than in rods. Thus, RGS9 is the predominant source of GAP activity in rod outer segments, and RGS9 concentration emerges as a potentially important determinant of the faster response kinetics and lower sensitivity of mammalian cones, as compared with rods.

RGS9, a GTPase accelerator for phototransduction.

The rod outer segment phototransduction GAP (GTPase-accelerating protein) has been identified as RGS9, a member of the RGS family of G alpha GAPs. RGS9 mRNA expression is specific for photoreceptor cells, and RGS9 protein colocalizes with other phototransduction components to photoreceptor outer segment membranes. The RGS domain of RGS9 accelerates GTP hydrolysis by the visual G protein transducin (G alpha(t)), and this acceleration is enhanced by the gamma subunit of the phototransduction effector cGMP phosphodiesterase (PDEgamma). These unique properties of RGS9 match those of the rod outer segment GAP and implicate it as a key element in the recovery phase of visual transduction.

A comparison of the efficiency of G protein activation by ligand-free and light-activated forms of rhodopsin.

Activation of the photoreceptor G protein transducin (Gt) by opsin, the ligand-free form of rhodopsin, was measured using rod outer segment membranes with densities of opsin and Gt similar to those found in rod cells. When GTPgammaS was used as the activating nucleotide, opsin catalyzed transducin activation with an exponential time course with a rate constant k(act) on the order of 2 x 10(-3)s(-1). Comparison under these conditions to activation by flash-generated metarhodopsin II (MII) revealed that opsin- and R*-catalyzed activation showed similar kinetics when MII was present at a surface density approximately 10(-6) lower than that of opsin. Thus, in contrast to some previous reports, we find that the catalytic potency of opsin is only approximately 10(-6) that of MII. In the presence of residual retinaldehyde-derived species present in membranes treated with hydroxylamine after bleaching, the apparent k(act) observed was much higher than that for opsin, suggesting a possible explanation for previous reports of more efficient activation by opsin. These results are important for considering the possible role of opsin in the diverse phenomena in which it has been suggested to play a key role, such as bleaching desensitization and retinal degeneration induced by continuous light or vitamin A deprivation.

Competitive and territorial fighting: two types of offense in the rat.

Two types of fighting (offense) were compared and contrasted in three experiments on the laboratory rat. In Experiment 1, competitive fighting was obtained in pairs of hungry cagemates by placing one food pellet into their food hopper. In Experiment 2, territorial fighting was obtained by introducing an unfamiliar intruder into the home cage of a male and female pair. Both types of fighting had the same motor patterns. Whereas territorial fighting is strongest against intruders of the same sex, competitive fighting is stronger against the smaller opponent (in this case female) regardless of the sex of the test animal. Whereas territorial fighting is stronger in males, competitive fighting is stronger in females. Whereas gonadectomy reduces territorial fighting in males but not females, it reduces competitive fighting in both sexes. In experiment three, it was shown that food deprivation increases competitive fighting, while it reduces territorial fighting. On the basis of these findings a revised model of the organization of the offense motivational system is proposed.

Offense produced by chemical stimulation of the anterior hypothalamus of the rat.

Offense behavior, including bite-and-kick attack, was obtained by microinjections of picrotoxin into the anterior hypothalamus of the rat. This is the first time that it has been possible to obtain offense by chemical stimulation of the brain, and the localization is more precise than that obtained with electrical stimulation. Mounting behavior and mounting by the opponent were also obtained from the anterior hypothalamus, the former corresponding to results obtained by previous studies using electrical stimulation. Other behaviors obtained from the hypothalamus included locomotion and circling, social and self-grooming, upright posture and boxing, digging, feeding, and leaping.